首页|基于AlGaN/GaN HEMT外差探测器的太赫兹线阵列矢量探测系统

基于AlGaN/GaN HEMT外差探测器的太赫兹线阵列矢量探测系统

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为 了研究 AlGaN/GaN 高电子迁移率晶体管(High-Electron-Mobility Transistor,HEMT)外差探测器应用于太赫兹来波方向(Direction of Arrival,DOA)估计领域的可行性及量化性能指标,基于AlGaN/GaN HEMT 243 GHz外差探测器搭建了太赫兹波线阵列矢量探测系统,实现了太赫兹连续波的相位分布和来波方向的测量.该系统的核心器件为准光-波导耦合的太赫兹外差探测器线阵列组件,阵元平均噪声等效功率(Noise-Equivalent-Power,NEP)为-123.89 dBm/Hz.通过测试,表明该系统相位解析稳定度优于0.6°,线阵列组件法线(阵列芯片的垂线)方向左右11°以内的太赫兹来波方向的检测误差小于0.25°.讨论了存在误差的原因及可能的解决方案,为后续基于AlGaN/GaN HEMT面阵列的太赫兹相控阵雷达及定向通信系统的研制提供了基础.
Arrayed terahertz vector measurement system based on AlGaN/GaN HEMT heterodyne mixer
Objective To investigate the feasibility and quantify performance metrics of AlGaN/GaN high-electron-mobility transistor(HEMT)heterodyne detectors in the domain of terahertz direction of arrival(DOA)estimation,this study benefits from the high bandwidth and resolution characteristics of terahertz waves,as well as the process consistency and scalability of AlGaN/GaN high-electron-mobility transistor terahertz heterodyne mixers.A 243 GHz linear array vector detection system based on these mixers was designed and constructed,characterizing its various performance attributes.Methods This paper establishes a 243 GHz linear array vector detection system based on an AlGaN/GaN HEMT mixer linear array(Fig.1(a)).The transmitted terahertz waves to be measured are collimated by an off-axis parabolic mirror(OAP).The receiver uses a high-speed multi-channel ADC array to collect signals from the mixer array,which have been amplified by an intermediate frequency signal amplifier,for processing in the higher-level computer.The processing flow(Fig.2(b))includes amplitude and phase resolution,calibration,and beamforming.Results and Discussions Testing demonstrates that the system's phase resolution stability is superior to 0.6°,with this error primarily stemming from the phase noise of the microwave source.Future use of a microwave source with lower phase noise and increasing the frequency of the system's intermediate frequency signal for heterodyne detection could further reduce this error.The system exhibits a phase distribution detection relative error of less than 3.6%,attributed to minor discrepancies introduced during the patch assembly of each channel's mixer.Employing more precise assembly techniques in the future could decrease this error.The system's error in detecting terahertz waves arriving from±11° of the normal direction is less than 0.25°,and the normalized level of the first sidelobe is around-3 dB,due to variations in the response consistency of each channel's mixer.Enhancing the consistency of mixers across channels or increasing the number of elements on the linear array could further reduce sidelobe levels and improve the accuracy of direction of arrival detection.The system's field of view reaches 22°,a result of the current 3 mm spacing between linear array elements leading to insufficient spatial sampling rates for terahertz waves and a limited field of view constrained by the 3 mm superhemispherical silicon lens used to couple the measured terahertz waves.Future efforts will focus on reducing the spacing between linear array elements and adopting a more optimal coupling method for the measured terahertz waves to enhance the overall field of view of the system.Conclusions This paper establishes a 243 GHz terahertz linear array vector detection system characterized by high phase resolution stability and low error in the direction of arrival detection.By comparing test results with simulation outcomes,it was found that the system's phase distribution detection error is less than 3.6%,the error in detecting terahertz wave direction of arrival within±11° of the normal direction is less than 0.25°,and the field of view reaches 22°.These results validate the feasibility of applying AlGaN/GaN HEMT heterodyne detector linear array components in the field of terahertz DOA estimation.This lays the groundwork for the subsequent development of terahertz phased array radars and directional communication systems with larger fields of view and smaller system sizes.

estimation of direction of arrival(DOA)terahertz wavearrayed detectorheterodyne(coherent)detectionAlGaN/GaN HEMT

王凯出、丁青峰、周奇、蔡昕航、张金峰、朱凯强、翟振钧、孙厚军、王林军、秦华

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上海大学材料科学与工程学院,上海 200444

中国科学院苏州纳米技术与纳米仿生研究所 中国科学院纳米器件与应用重点实验室,江苏苏州 215123

上海科技大学 物质科学与技术学院,上海 201210

中国科学技术大学 纳米技术与纳米仿生学院,安徽合肥 230026

北京理工大学 集成电路与电子学院,北京 100081

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太赫兹来波方向(DOA)估计 阵列混频器 外差(相干)探测 氮化镓HEMT

国家自然科学基金项目国家自然科学基金项目国家自然科学基金项目江苏省重点研发计划项目中国科学院青年创新促进会

619752276177146661775231BE20180052017372

2024

10.3788/IRLA20240088

红外与激光工程
中国航天科工集团公司第三研究院第八三五八研究所

红外与激光工程

CSTPCD北大核心
影响因子:0.754
ISSN:1007-2276
年,卷(期):2024.53(6)